EP2268940B1 - Incremental variable transmission - Google Patents
Incremental variable transmission Download PDFInfo
- Publication number
- EP2268940B1 EP2268940B1 EP09735836A EP09735836A EP2268940B1 EP 2268940 B1 EP2268940 B1 EP 2268940B1 EP 09735836 A EP09735836 A EP 09735836A EP 09735836 A EP09735836 A EP 09735836A EP 2268940 B1 EP2268940 B1 EP 2268940B1
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- EP
- European Patent Office
- Prior art keywords
- drive
- output
- chain
- machine according
- input
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
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Classifications
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F16—ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
- F16H—GEARING
- F16H9/00—Gearings for conveying rotary motion with variable gear ratio, or for reversing rotary motion, by endless flexible members
- F16H9/02—Gearings for conveying rotary motion with variable gear ratio, or for reversing rotary motion, by endless flexible members without members having orbital motion
- F16H9/24—Gearings for conveying rotary motion with variable gear ratio, or for reversing rotary motion, by endless flexible members without members having orbital motion using chains or toothed belts, belts in the form of links; Chains or belts specially adapted to such gearing
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F16—ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
- F16H—GEARING
- F16H55/00—Elements with teeth or friction surfaces for conveying motion; Worms, pulleys or sheaves for gearing mechanisms
- F16H55/32—Friction members
- F16H55/52—Pulleys or friction discs of adjustable construction
- F16H55/56—Pulleys or friction discs of adjustable construction of which the bearing parts are relatively axially adjustable
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F16—ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
- F16H—GEARING
- F16H9/00—Gearings for conveying rotary motion with variable gear ratio, or for reversing rotary motion, by endless flexible members
- F16H9/02—Gearings for conveying rotary motion with variable gear ratio, or for reversing rotary motion, by endless flexible members without members having orbital motion
- F16H9/24—Gearings for conveying rotary motion with variable gear ratio, or for reversing rotary motion, by endless flexible members without members having orbital motion using chains or toothed belts, belts in the form of links; Chains or belts specially adapted to such gearing
- F16H2009/245—Gearings for conveying rotary motion with variable gear ratio, or for reversing rotary motion, by endless flexible members without members having orbital motion using chains or toothed belts, belts in the form of links; Chains or belts specially adapted to such gearing with idle wheels to assist ratio change
Definitions
- This invention relates to a variable transmission (IVT) machine in which the ratio of an output rotational speed to an input rotational speed, of the machine, is adjustable in increments.
- IVT variable transmission
- the present invention aims to provide a variable transmission machine which is compact and which can transmit substantial power and in which the ratio of output to input speed can be varied in a large number of small increments so that, for practical purposes, the output speed does not change in a step-wise manner. It is also an object of the present invention to provide an integrated chain tensioning system with a simple, robust and integrated mechanical shifting mechanism thereby to avoid the use of hydraulic arrangements.
- the last mentioned aspect is of particular significance for, by way of example, a hydraulic pump, in an IVT machine which has a hydraulic control system, runs continuously and can consume up to 5% or 6% of the available power.
- variable transmission machine which includes a cam arrangement which, in response to an output device, oscillates through a reference position.
- This document fails to disclose an actuator which is operable with the cam arrangement in the reference position, to vary the speed of the output drive in an accurate, incremental manner and which enables the machine to be of compact construction.
- the invention provides a variable transmission machine which includes an input drive having the features of claim 1.
- the actuating mechanism may include a single actuator which is used to cause the second speed to be increased, or decreased, according to requirement.
- the actuating mechanism may include a single actuator which is used to cause the second speed to be increased, or decreased, according to requirement.
- at least first and second actuators are used to cause an increase, or a decrease, in the second speed by an increment.
- the first position of the cam arrangement may be a first limiting position which is displaced by a first angle in a first direction of rotation from the reference position.
- the second position may be a second limiting position which is displaced by the first angle in a second direction of rotation, which is opposite to the first direction, from the reference position.
- the cam arrangement may provide a first dwell period when the cam arrangement is at the first limiting position and, during the first dwell period, the actuating mechanism may be operable.
- a second dwell period may be provided when the cam arrangement is at the second limiting position and the actuating mechanism may be operable during the second dwell period.
- each actuator in the actuating mechanism includes a respective solenoid and, using techniques which are known in the art and which are not further described in this specification, the actuators are operated by a suitable control unit e.g. a microprocessor or similar device.
- a suitable control unit e.g. a microprocessor or similar device.
- the cam arrangement may be used with various machines which have different input drives and different output drives.
- the cam arrangement is used with a machine which is, in general terms, similar to the machine described in the earlier specification.
- the disclosure in the earlier specification is hereby incorporated into this specification.
- the output drive includes axially aligned, opposing first and second conical discs which are spaced apart and which are rotatable about the output axis
- the controller includes a screw assembly which acts between the first and second discs and which is operable in a first mode, upon operation of the actuating mechanism to increase the spacing between the discs by a first amount and so increase the second speed by an increment, and which is operable in a second mode, upon operation of the actuating mechanism, to decrease the spacing between the discs by a second amount and so decrease the second speed by an increment.
- the actuator which typically is a solenoid, must be capable of exerting sufficient force, within a defined period, to operate effectively.
- the aforementioned discs may, generally, be of the type described in the earlier specification.
- a drive chain may be used to transfer rotational drive from the input drive to the output drive and the drive chain may, in general terms, be similar to what has been described in the earlier specification.
- the input drive may include an input shaft which is rotatable about the input axis, an idler which is mounted for rotation about the input axis, a first swing arm which is mounted for limited pivotal movement about the input axis, a first drive sprocket on the first swing arm, a second swing arm which is mounted for limited pivotal movement about the input axis, a second drive sprocket on the second swing arm, the drive chain being engaged with the first and second drive sprockets and passing over the idler, and a gear assembly which, upon rotation of the input shaft, causes rotation of the first and second drive sprockets thereby to cause rotation of the output drive.
- the swing arms may extend from the input axis in divergent directions, which vary as the drive ratio (the ratio of the second speed to the first speed) changes.
- the swing arms for any given directions i.e. operative positions, may be mounted to have a small degree of pivotal movement. This may be achieved by providing a first stop which restricts pivotal movement of the first swing arm when a first portion of the drive chain between the first sprocket and the output drive is tensioned. Similarly a second stop may be provided which restricts pivotal movement of the second swing arm when a second portion of the drive chain between the second sprocket and the output drive is tensioned.
- the first stop may include a first biasing mechanism which acts to tension the first portion of the drive chain when the second portion of the drive chain is tensioned and, similarly, the second stop may include a second biasing mechanism which acts to tension the second portion of the drive chain when the first portion of the drive chain is tensioned.
- the first and second drive sprockets may be mounted to respective shafts for relative axial movement along the shafts when the spacing between the first and second discs is varied.
- the machine preferably includes a mechanism which, in response to incremental changes in the second speed, adjusts the tension in the drive chain by adjusting the positions of the swing arms.
- Power can flow through the machine in different directions. For example, in a vehicular application, power is transferred from an engine through the machine to drive wheels of the vehicle. If however engine braking takes place e.g. the vehicle goes downhill with reduced engine power output, power flows through the machine in a reverse direction.
- the machine may include a support slide structure which is movable laterally relative to the output axis, and first and second guide idlers which are mounted to the support slide structure, which are engaged with the drive chain and which are spaced apart to form a gap through which opposing portions of the drive chain pass to, and from, the output drive respectively and wherein, in response to incremental movement of the cam arrangement, the support slide structure and the first and second guide idlers move and cause incremental pivotal movement of the first and second swing arms.
- the first stop is movable, in response to movement of the first swing arm and the action of the first biasing mechanism from a first stop position through a first gap with a maximum width of 2L
- the second stop is movable, in response to movement of the second swing arm and the action of the second biasing mechanism from a second stop position through a second gap with a maximum width of 2L and wherein the sum of the first gap and the sum of the second gap is 2L.
- a preload tension in the drive chain is preferably determined by the two biasing mechanisms.
- FIG. 1 illustrates different aspects and parts of a machine 10 according to the invention.
- the components of the machine are mounted in any appropriate housing 12 (shown notionally, when required, by a dotted line) in which are formed various slots and support structures, as may readily be determined by a person skilled in the art, to support components, moving or stationary, of the machine.
- a chain 14 located externally of the housing, passes over cogs 16 and 18 respectively.
- Meshing gears 22 and 24 are on an outer side of the housing.
- the machine has an input drive 26 and an output drive 28.
- Figure 4 shows, in an exploded configuration, the input drive 26 which includes an input shaft 30 with an input sprocket 32 at one end and a bearing 33 at an opposed end.
- a shaft 34 is positioned to one side of the input shaft and has a sprocket 36 fixed to it which meshes with the input sprocket 32.
- the shaft 34 is formed with splines 38.
- An axially slidable chain drive 40 which includes two spaced apart sprockets 42 and 44 respectively, is mounted to the shaft 34.
- a drive shaft 34A is positioned on an opposing side of the input shaft.
- the shaft is similar in construction to the shaft 34 and carries a chain drive 40A with similar components to the chain drive 40, which are identified with the suffix A.
- the input drive includes a lower swing arm 46, an upper swing arm 48 and a tubular idler 50.
- the lower swing arm 46 has spaced arms 46A and 46B respectively which extend from a tube 52.
- a projection on the arm 46A forms a cam lever 54 with a cam lobe 56.
- the arms 46A and 46B have bearings 58A and 58B respectively mounted to them.
- the upper swing arm 48 is of similar construction to the lower swing arm and includes a tube 62 from which extend spaced arms 48A and 48B respectively. Each arm has a corresponding bearing 64A and 64B.
- the arm 48A is extended to form a cam lever 66 with a cam lobe 68.
- the idler 50 is fitted with inner needle bearings 70.
- the shaft 30 When the input drive is assembled the shaft 30 extends through the tube 62 which is inside the tube 52.
- the idler 50 is on an outer side of the tube 52.
- the chain drive 40 is between the arms 48A and 48B.
- the shaft 34 is supported by the bearings 64A and 64B.
- the chain drive 40A is between the arms 46A and 46B and the shaft 34A is supported by the bearings 58A and 58B.
- the sprockets 32, 36 and 36A are identical in that they have the same diameter and the same number of teeth.
- a chain 240 (see for example Figure 1A ) which transfers drive between the input drive 26 and the output drive 28, has the same pitch circle PC (see Figure 22 ) as it passes over the sprockets 42 and 44, and 42A and 44A, and the idler 50.
- the output drive 28 (see primarily Figures 5, 6 and 7 ) has an outer disc 80 with a conical face 82 in which are formed a plurality of precisely positioned grooves 84.
- the outer disc faces an inner disc 86 which has a generally similar construction i.e. a substantially conical face 88 in which are formed a plurality of precisely positioned grooves 90.
- An output drive shaft 92 is fixed to the outer disc 80.
- a tubular boss 94 extends from the disc 80 and surrounds a part of the shaft 92.
- Two diametrically opposed grooves 96 extend axially in an outer surface of the boss 94 - (only one groove is visible in Figure 6 ).
- a tubular formation 100 extends from the disc 80 and surrounds and is spaced from an outer surface of the boss 94.
- the inner disc 86 has a tube 102 which fits closely inside an annular gap 104 between opposing surfaces of the boss 94 and the tubular formation 100.
- An inner surface of the tube 102 is formed with diametrically opposed grooves 108, see Figure 7 .
- Ball-bearings, not shown, are located in the grooves 96 and 108 so that one disc can be moved axially relative to the other disc but without allowing rotation of one disc relative to the other.
- the cog 16 and the gear 24 ( Figure 1A ) are fixed to an end of the shaft 92.
- the inner disc 86 on an outer face 114, has a raised boss 118 which carries a thrust bearing 120 and a needle bearing 122.
- the boss 118 on a surface which opposes the outer face 114, is formed with an axially oriented cam lobe 126 which has up and down ramps 126A. 126B of equal magnitude. Each ramp extends through an angle of about 60°. The sum of the angles through which the ramps are operative is thus about 120°. This is reflected in the curve 590 in Figure 24 (described hereinafter) which graphically depicts the movement of a cam follower 316 ( Figure 16 ) which rides on the cam lobe.
- the outer disc On its outer side 130 ( Figure 7 ) the outer disc has a bearing 132 which supports the shaft 92.
- a ball screw arrangement 136 includes a tube 138 with an external spiral groove 140. On an inner side the tube 138 has needle bearings 142 which are rotatably engaged with the shaft 92. A worm gear wheel 144 at one end of the tube is backed by a thrust bearing 146 and a bearing 148 which is supported by the housing 12.
- a ball screw unit 150 includes an inner hub 152 ( Figure 7 ) which, on an inner surface, has a female ball screw thread 154 which includes a feedback path for ball-bearings, not shown, which are mated with the spiral groove 140 on the tube 138.
- the inner hub extends from a generally circular body 160 with a rim 162 in which are formed a plurality of hemi-spherical indentations 164 at angular spacings of 45°.
- Figure 6A is an enlarged view of the body 160 and illustrates in better detail constructional aspects of the body.
- Figure.6B shows, on a greater scale additional aspects of a portion of the body 160.
- the body 160 has inwardly tapered lock holes 174 which are angularly spaced from one another by 45°. Each lock hole is centrally positioned between a respective adjacent pair of indentations 164.
- a circular ball-bearing thrust groove 176 is located inwardly of the lock holes 174.
- a circular raised portion 180 on the body is formed with four arcuate slots 182. Each slot extends through an angular displacement of 45° (as indicated) and follows a radius R relative to a central longitudinal axis 186 of the output drive shaft 92. Adjacent slots are angularly separated by 45° (as indicated). Each slot has two ramps 188A and 188B which slope downwardly and outwardly from a central position 190 which is coplanar with an outer surface of the raised portion 180, towards respective deep ends 190A and 190B, defined by respective blind holes.
- a central tubular formation 192 on the body 160, supports a washer 194 which is held in position by means of a circlip, not shown.
- An inner side of the body 160 abuts the thrust bearing 120 and an outer surface of the inner hub 152 is engaged with an inner surface of the bearing 122.
- Figure 5 shows the assembled output drive 28.
- the effect of the ball screw arrangement 136 is such that, if rotation of the tube 138 is constrained, rotation of the body 160 in one direction will cause the inner disc 86 to be moved axially towards the outer disc 80. Conversely, counter-rotation of the body 160 causes the axial displacement between the discs 80 and 86 to be increased.
- Figure 8 shows an outer support slide 200 while Figure 9 shows an inner support slide 202.
- the support slide 200 has spaced plates 204 and 206 respectively braced by rods 208A to 208D.
- a small plate 210 with a cam surface 212 extends between the plates and is flanked by opposing slots 214 and 216 in the plates 204.
- Extension pieces 220 and 222 on the plate 206 carry stops 224 and 226 respectively at their extremities. The function and construction of the stops are described hereinafter.
- the inner support slide 202 has two plates 228 and 230 which are spaced apart by supporting rods 232. Two closely spaced guide idlers 234 and 236 are rotatably supported between the plates on suitable shafts 234A and 236A respectively.
- the inner support slide 202 is positioned between the plates 204 and 206 of the outer support slide.
- the rods 208A to 208D are passed through registering pairs of holes 238A to 238D, respectively.
- the resulting composite slide assembly 239 is located between the input drive 26 and the output drive 28 (see Figure 2 ) and is supported by the housing 12 of the machine so that it can move, as required, during operation of the machine with a sliding action away from the input drive and towards the output drive, and vice versa.
- a chain 240 (shown notionally) passes through gaps between the chain drive 40 and the idler 50 on the one hand, and the idler 50 and the chain drive 40A on the other hand. Opposing portions of the chain pass through a gap between the guide idlers 234 and 236. The remainder of the chain forms a loop 241 between opposing surfaces of the outer disc 80 and the inner disc 86.
- the chain is engaged with the sprockets 42 and 44, and 42A and 44A, and is used to transfer rotational drive between the input drive 26 and the output drive 28.
- the chain has a plurality of pins which connect links of the chain to each other and ends of the pins, which project outwardly beyond the links, are engaged with the grooves 84 and 90 in opposing surfaces of the two discs. This direct mechanical interengagement of complementary formations ensures that positive drive (as opposed to frictional drive) is transferred from the input drive to the output drive.
- the construction of the chain and the way in which drive is transferred from the input drive 26 to the output drive 28 are generally in accordance with the description in the earlier specification and these aspects are not further elaborated on herein.
- the pitch circle (PC) of the chain does not vary as it passes around the sprockets 42 and 44, and 42A and 44A, and the idler 50.
- tensile forces exerted by the chain lengths 241A and 241 B ( Figure 23 ) extending from the idler are minimal.
- the idler is thus effectively isolated from these forces.
- Figure 10 shows a composite cam arrangement 242 which includes an oscillating drive unit 244, shown in different perspective views in Figures 11 and 12 , a locking plate 246 which is shown in different perspective views in Figures 13 and 14 , first and second cams 248 and 250 shown in Figures 17 and 18 respectively, and an actuating lever 252 shown in Figure 19 .
- the locking plate 246 has a body 262 with a central bore 264 in which is located a needle bearing 266.
- Two solenoids 268 and 270 respectively are mounted to a face of the body.
- the solenoids have respective plungers 272 positioned on central longitudinal axes 276 and 278 which are angularly spaced apart by 45° determined with reference to a longitudinal axis 280 of the bore.
- Each axis 276, 278 is a radial distance R away from the axis 280. This distance equals the radius R shown in Figure 6A .
- the body 262 has a lobe 282 in which is formed a hole 284.
- the needle bearing 266, in the assembled form of the machine, is rotatably engaged with the tubular formation 192 on an outer face of the body 160 shown in Figure 6 .
- Figure 15 shows the construction of the solenoid 270 - the solenoid 268 is of identical construction.
- the solenoid has a housing 290 in which is located an annular electric coil 292.
- a spring 294 which extends through the coil acts on the plunger 272 which is of tubular form and which is flanked by a circular rim 298 against which the coil 292 bears.
- An outer end of the plunger is located in a plunger hole 300 in the body 262.
- each solenoid is such that, with power applied to the respective coil 292, the plunger is held in the casing 290. If the power supply is interrupted the plunger is forced outwardly, away from the casing by virtue of the biasing force of the spring 294 and an outer extremity of the plunger then protrudes beyond a surface 304 of the body 262.
- Figure 16 illustrates a locking unit 310 which includes a plate 312 from which extends a shaft 314.
- a cam follower 316 is attached to a stud 318 which projects transversely from an end of the shaft 314.
- a locking stud 320 is attached to the plate 312 by means of a nut 322.
- the stud has a tapered end 324.
- the oscillating drive unit 244 ( Figures 11 and 12 ) includes a plate 342 with a circular hole 344.
- a lock structure 346, attached to the plate, has a block 348 with upper and lower holes 348A and 348B, and two spaced passages in which are located compression springs 350 and 352 respectively.
- the oscillating drive unit 244 also includes a bearing plate 1000 with a thrust ball bearing groove 1002, concentric with the hole 344, in which ball bearings (not shown) operate to mate and bear against the ball bearing thrust groove 176 in the body 160.
- a locator block 354 projects radially from the plate 342.
- a bolt 356 is threadedly engaged with a passage 358 (shown in dotted lines in Figure 12 ) which extends through the block.
- An inner end of the bolt bears against a spring 360 which in turn acts on a ball bearing 362 which protrudes slightly through a mouth of the passage which, in the assembled configuration of the machine, is close to the rim 162 of the body 160 ( Figure 7 ) so that the spring loaded ball-bearing 362 can engage with a respective hemi-spherical indentation 164.
- the engagement configuration is maintained until sufficient torque is applied to the body 160 to enable the compressive force of the spring 360, which acts on the ball bearing 362, to be overcome. Relative rotational movement between the locator block 354 and the body 160 can then take place, until the ball bearing enters the following hemi-spherical indentation.
- a stud 364 projects from the plate 342 and an angled lever 366, fixed to the plate, extends from the stud.
- a remote end of the lever has a stud 368 which is slidably located in a first slot (not shown) in the housing 12.
- the stud 364 slides in a second slot (not shown) which is in the housing and which is parallel to the first slot.
- Bearing pairs 370 and 370A, and 372 and 372A, respectively are provided on spaced plates 378 and 380 which are interconnected by means of studs 382.
- the plate 378 has a projection 386 with parallel slots 388.
- a base plate 394 straddles the slots and is connected thereto by means of fasteners 396 which pass through slots 398 in the base plate which are transverse to the slots 388.
- a swivel stud 400 projects laterally from the base plate.
- Another stud 402 is centrally positioned on the plate 380 between the bearings 370A and 372A.
- the first cam 248 ( Figure 17 ) includes a cam profile 422 projecting from a splined hollow shaft 424.
- a spur gear 426 is carried by the shaft.
- the second cam 250 ( Figure 18 ) has a splined hollow shaft 432 which carries a second cam profile 434 and a spur gear 436.
- the actuating lever 252 ( Figure 19 ) is formed from two spaced plates 442 and 444 respectively.
- a cam follower 446 is rotatably mounted between the plates at an intermediate position.
- a pin 448 is mounted between the plates, on a front side of the cam follower, a distance C from a central axis of the cam follower.
- Slots 450 are formed in opposing surfaces of the plates on a second side of the cam follower.
- the cam follower 446 is located between the cam profiles 422 and 434 which act as a conjugate cam pair.
- Figure 10 illustrates how the oscillating drive unit 244, the locking plate 246, the first and second cams, and the actuating lever, are assembled to make up the composite cam arrangement 242.
- the swivel stud 400 passes through the slots 450.
- a central axis of the stud is a distance D from the rotational axis of the cam follower 446 ( Figure 19 ).
- the pin 448 is engaged with the hole 284 in the locking plate 246.
- the first and second cams are respectively mounted to the opposed bearing pairs 370 and 370A, and 372 and 372A.
- the bore 264 of the body 262 is in register with the hole 344.
- the locking unit 310 is engaged with the lock structure 346.
- the shaft 314 extends through the upper hole 348A while the stud 320 extends into the lower hole 348B.
- the springs 350 and 352 abut an opposing surface of the plate 312.
- the spur gears 436 and 426 of the two cams are meshed with an intervening gear 480 which is mounted to the stud 402.
- the gear 22 ( Figure 2 ), attached to a splined shaft 492 which extends through and drives the splined shaft 424 of the first cam, has a diameter which is twice the diameter of the spur gear 24.
- An angled lever 500 has a rectangular slot 502 which is slidably engaged with a block 504 which is rotatably mounted to the stud 364.
- a pin (not shown), fixed to the housing 12, is rotatably engaged with the lever by locating the pin in a hole 506.
- a limb 508 of the lever extends through the slot 216 in the plate 206 of the outer support slide and bears on the cam surface 212 ⁇ see Figure 2 .
- a similar construction is provided at an opposing limb 510 of the cam arrangement 242.
- the chain 240 when passing around the discs, travels on a substantially circular loop 241 of a relatively large radius R1, see Figure 22 .
- the swing arms 46 and 48 are pivoted towards the discs and the chain drives 40 and 40A of the input drive are moved towards the discs.
- the composite slide assembly 239 is moved to the right towards the idler 50, to allow for the relatively large radius R1 of the loop 241. If the discs are moved apart the radius R2 of the chain looped around the discs is reduced, see Figure 23 .
- the swing arms are pivoted away from the discs, to take up the resulting slack in the chain.
- the composite slide assembly moves to the left to maintain the loop 241 as close as possible to a circle.
- each swing arm to a line 520 which passes through the centres of rotation of the discs and of the idler 50 changes from a minimum angle 522, see Figure 22 , to a maximum angle 524, see Figure 23 .
- a significant benefit of this process is that the movement of the swing arms is such as to maintain the chain 240, essentially tensioned to the requisite degree, as operating conditions change.
- the present invention is also concerned with providing a smooth and reliable change in the ratio of the output speed to the input speed of the machine, on an incremental basis, in an effective manner.
- the gear 22, meshed with the gear 24, drives the cam arrangement in a 2:1 ratio in the opposite direction.
- the spur gear 426 is rotated together with the gear 22 and, via the idler gear 480, the spur gear 436 is rotated.
- the cam follower 446 is acted on by the first and second cam profiles 422 and 434 and the lever 252 is thereby oscillated about the stud 400.
- the pin 448 is connected to the locking plate 246 which is oscillated through an amplitude of 45° about the axis 280.
- the position of the locking plate 246 is graphically depicted by a curve 566 in Figure 24 .
- the rotational velocity of the plate is shown by a curve 526.
- Figure 3 shows the actuating lever 252 in a central or reference position.
- a line 530 shows the extent to which a central axis 532, also referred to as a reference position, of the lever is deflected to a maximum angular extent in a clockwise direction about the stud 400 and a line 534 shows the central axis of the lever deflected to a maximum, equal, angular extent in an anticlockwise direction about the stud.
- the springs 350 and 352 which are compressed when the cam follower 316 is on the up ramp, expand to cause the stud to disengage from the lock hole 174, when the cam follower is on the down ramp 126B.
- the ball screw unit 150 is held in position by the spring-loaded ball bearing 362 ( Figure 12 ) which is engaged with a respective hemi-spherical indentation 164 and the plungers 272 of the solenoids are retracted and held in the positions shown in Figure 13 .
- the tapered end 324 of the stud 320 repeatedly engages with, and disengages from, the respective tapered lock holes 174. In this way the ball screw unit 150 is accurately aligned with the ball screw arrangement 136 at periodic intervals - this is required particularly after ratio shifting has taken place.
- the position of the stud 324 is reflected by the curve 580 in Figure 24 .
- Ratio changing is preferably effected by means of an appropriate electronic control unit.
- the manner in which the control unit operates is apparent to one skilled in the art and is not described herein. What is required from the control unit is the ability to direct a signal to a selected solenoid at a precisely controlled interval which is related to the operation of the machine, in response to various input signals.
- the electronic control unit determines in which direction the ball screw unit 150 is to be rotated. Operation in one direction increases the ratio, while operation in the reverse direction decreases the ratio, in each case by a small increment.
- the electronic control unit determines which solenoid 268 or 270 is to be operated.
- a curve 558 in Figure 24 shows movement of the cam follower 446, on each side of a reference line 532A which represents the reference axis 532 as the lever 252 oscillates.
- the cam profiles 422 and 434 produce respective dwell periods 560 and 562, for rotational periods of 60° of the cams, at the end of each cam lift (564) and cam drop (566) phase. Each phase extends through 120°.
- the oscillating locking plate 246 is stationary.
- power to the selected solenoid 268, 270 is interrupted and the plunger 272 of that solenoid is immediately moved under the action of its biasing spring 294 to stand proud of the surface 304.
- the solenoid selection is based on the rotation direction of the oscillating locking plate after its current dwell duration.
- the emerging plunger 272 is directed into engagement with the corresponding arcuate slot 182 in the body 160.
- the oscillating locking plate starts moving in the reverse direction and, as the plunger is engaged with the deep hole end of the arcuate recess, the body 160 is thereby rotated together with the locking plate through 45°.
- the ball screw unit 150 is also driven through 45° and, depending on the direction of rotation of the unit 150, the inner disc 86 is moved towards or away from the outer disc 80 by a small predetermined amount. This results in an incremental change of the output speed of rotation compared to the input speed of rotation.
- the oscillating locking plate reaches its next dwell period.
- the ball screw unit 150 is locked in position by the tapered stud 320 of the locking unit 310 which engages with the corresponding lock hole 174, in the body 160, which is in register with the stud.
- the solenoid which had been deactivated is then re-energised by the control unit.
- the plunger of this solenoid rides up the ramp surface 188A or 188B in the respective arcuate slot and is then held in the retracted position, inside the housing 290, by the energised solenoid coil 292.
- An incremental change in the drive ratio can thus be effected, up or down, for every two rotations of the discs 80 and 86.
- the actuating mechanism includes two actuators (solenoids) to increase the output speed incrementally, and to decrease the output speed incrementally.
- a single solenoid can however be used to replace the two solenoids provided the coil of the single solenoid is sufficiently powerful to retract the solenoid plunger against the bias of a spring (equivalent to the spring 294) and against all frictional forces, at a speed which meets operational requirements.
- the four arcuate slots 182 on the raised circular portion 180 of the unit 150 are replaced by respective blind holes which are concentric with, and substantially of the same diameter as, the deep ends 190 of the slots.
- the single solenoid is then operated directly in place of the two solenoids to cause rotation of the unit 150 in one direction, or the other, through a predetermined angle.
- Figure 3 illustrates X and Y axes which are centred on the axis of the swivel stud 400 but which are shown displaced from this axis.
- the dimensions C and D marked in Figure 19 are shown in Figure 3 .
- the central axis of the stud 400 can be adjusted in the X-direction, or in the Y-direction, within reason, according to requirement, by moving the plate 394 in one way or the other after the fasteners 396 have been loosened. The degree of movement, possible in this way, is limited by the dimensions of the slots 388 and 398.
- a further factor is that by adjusting the stud 400 in the Y direction a phase shift of oscillation of the oscillating locking plate 246 is achieved. This adjustment can be used to ensure that the solenoid units are precisely in register with the respective deep hole ends of the recessed slots 182 during the cam dwell periods 560 and 562 shown in Figure 24 .
- Ends of the chain 240 must be positioned to engage accurately with the grooves in the discs. This alignment can be affected by wear, temperature and by torque applied to or generated in the machine.
- a worm gear 600 which is mounted to a shaft 602 which is rotatably supported by the housing 12.
- the worm gear 600 is engaged with the worm gear wheel 144 - Figure 3 .
- the shaft 602 could be rotated by an electrical motor, not shown, in small increments, preferably under the control of the electronic control unit referred to, to ensure precise adjustment of the operation of the machine on an ongoing basis.
- Rotation of the shaft 602 causes rotation of the ball screw arrangement 136, relative to the unit 150, and causes movement of the disc 86 relative to the disc 80.
- the adjustment of the worm gear could be done in response to an algorithm established after calibration routines. Alternatively it could be done by a processor which operates in a real time, feedback mode to ensure precise synchronisation.
- each stop includes springs 606, inside a housing 608, which bias a support plate 610 outwardly.
- the cam lobes 56 and 68 of the swing arms, described in connection with Figure 4 bear against the respective support plates 610.
- Figure 20 shows only the lower lobe 68. In a neutral position the spacing between each support plate and its housing is a distance L.
- the small degree of relative movement which is permitted and controlled by this arrangement is important for one of the swing arms (46 or 48) experiences a larger force than the other swing arm (48 or 46 as the case may be) when the machine is outputting power, or when the machine is absorbing power, for example due to engine braking.
- the high tension portion (say 652) exerts force on the corresponding cam lever which causes the gap L on the corresponding stop to be reduced to zero.
- the gap on the other stop is doubled to 2L. This causes a preload tension in the chain section which otherwise would have a much reduced chain tension.
- the benefit of this feature is that the part of the chain 240, between the chain drives 40 and 40A, which passes over the idler 50, is only subjected to the preload tension in the chain, and not to the load tension in the chain.
- the chain 240 tends to push the discs 80 and 86 apart.
- the disc 80 is however not axially movable.
- the swing arms act as stops which, via the respective levers, exert a force on the ball screw arrangement (on the outer side of the disc 86) which tends to push the disc 86 towards the disc 80, to counteract the effect of the chain.
- FIGs 20 and 21 illustrate a chain positioning system 700, which acts on the chain drive 40A, and which assists in achieving this function.
- the upper chain drive 40 has a similar system.
- the system includes a compression spring 702 on the drive shaft 34A which acts between the arm 46A and the sprocket 42A.
- a pin 704 which is slidably located in a passage formed in the shaft 34A at one end, has a circular disc 706 which bears against the ends of push-plates 708 which are slidably located in corresponding grooves 710 of spline formations in the shaft.
- the pin has a hemi-spherical end 712 which bears against a sloped rib 714 of a chain position guide 716 mounted in a semicircular slot 718 in the housing 12.
- the end of the pin rides over the sloped rib 714 in one direction or the other according to the movement of the swing arms 46 and 48. If the arms are moved away from each other, as depicted in Figure 23 , the pin is urged to the left (referring to Figure 21 ) by the sloped rib 714 and the sprockets 42A and 44A are moved to the left as the spring 702 is compressed. If the arms 46, 48 are moved in the opposing direction (towards each other as shown in Figure 22 ) the pin can move to the right and thus exerts less pressure on the spring which then moves the sprockets 42A, 44A to the right. In this way positive displacement of the sprockets occurs according to requirement.
- Figures 1A and 1B depict an input transmission shaft 800 on which is located a freely rotatable hub 802 which includes the chain drive 14 to the output drive shaft 92, a chain drive 806 to a freely rotatable sprocket 808 on a transmission output 810, and a gear drive 812 to a freely rotatable gear 814 located on the transmission output 810.
- a freely rotatable gear 816 is located on the transmission input shaft 800 and is meshed with a gear 818 which is fixed to the input shaft 30.
- a dog clutch 820 is used to couple the input shaft 800 to the gear 816 or to couple the shaft 800 to the hub 802, according to requirement.
- a second dog clutch 822 is used, as required, to couple the transmission output 810 to the gear 814, or to couple the output 810 to the gear 818 while having a central neutral position.
- a third dog clutch 824 couples the transmission output 810 to the sprocket 808 or decouples these components, as the case may be.
- a solid arrow line 900 indicates power input to the transmission and a broken arrow line 902 indicates power output from the transmission.
- the dog clutch 820 couples the transmission input shaft 800 to the gear 816 and the dog clutch 822 couples the transmission output shaft 810 to the gear 814. Power thus flows from the transmission input shaft 800 to the gear 816, then to the gear 818 and into the machine input end. Power then flows out of the machine to the chain drive 14 to the gear drive 812, to the gear 814 and then to the transmission output shaft 810. Reverse is accomplished by decoupling the dog clutch 822 while using the dog clutch 824 to couple the sprocket 808 to the transmission output shaft 810.
- the dog clutch 820 couples the transmission input shaft 800 to the hub 802.
- the dog clutch 822 couples the transmission output shaft 810 to the gear 818. Power thus flows from the transmission input shaft 800 to the hub 802, through the chain drive 14 and into the machine. Power flows out of the machine to the gear 818 and to the transmission output shaft 810.
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Abstract
Description
- This invention relates to a variable transmission (IVT) machine in which the ratio of an output rotational speed to an input rotational speed, of the machine, is adjustable in increments.
- The specification of International application number
PCT/ZA2004/000023 - The present invention aims to provide a variable transmission machine which is compact and which can transmit substantial power and in which the ratio of output to input speed can be varied in a large number of small increments so that, for practical purposes, the output speed does not change in a step-wise manner. It is also an object of the present invention to provide an integrated chain tensioning system with a simple, robust and integrated mechanical shifting mechanism thereby to avoid the use of hydraulic arrangements. The last mentioned aspect is of particular significance for, by way of example, a hydraulic pump, in an IVT machine which has a hydraulic control system, runs continuously and can consume up to 5% or 6% of the available power.
The closest prior art documentWO 2007/037747 describes a variable transmission machine which includes a cam arrangement which, in response to an output device, oscillates through a reference position. This document fails to disclose an actuator which is operable with the cam arrangement in the reference position, to vary the speed of the output drive in an accurate, incremental manner and which enables the machine to be of compact construction. - The invention provides a variable transmission machine which includes an input drive having the features of
claim 1. - Depending on operational factors, the actuating mechanism may include a single actuator which is used to cause the second speed to be increased, or decreased, according to requirement. In a different approach though at least first and second actuators are used to cause an increase, or a decrease, in the second speed by an increment.
- The first position of the cam arrangement may be a first limiting position which is displaced by a first angle in a first direction of rotation from the reference position. The second position may be a second limiting position which is displaced by the first angle in a second direction of rotation, which is opposite to the first direction, from the reference position. The cam arrangement may provide a first dwell period when the cam arrangement is at the first limiting position and, during the first dwell period, the actuating mechanism may be operable. Similarly, a second dwell period may be provided when the cam arrangement is at the second limiting position and the actuating mechanism may be operable during the second dwell period.
- It is possible for the actuating mechanism to be operated mechanically or electrically, in a predetermined manner, or via human intervention. Preferably each actuator in the actuating mechanism includes a respective solenoid and, using techniques which are known in the art and which are not further described in this specification, the actuators are operated by a suitable control unit e.g. a microprocessor or similar device. Although this aspect is important to effective operation of the machine it has no direct bearing on an understanding of the inventive principles embodied in the machine.
- The cam arrangement may be used with various machines which have different input drives and different output drives. In a preferred application of the principles of the invention the cam arrangement is used with a machine which is, in general terms, similar to the machine described in the earlier specification. The disclosure in the earlier specification is hereby incorporated into this specification. Thus, in a preferred application, the output drive includes axially aligned, opposing first and second conical discs which are spaced apart and which are rotatable about the output axis, and the controller includes a screw assembly which acts between the first and second discs and which is operable in a first mode, upon operation of the actuating mechanism to increase the spacing between the discs by a first amount and so increase the second speed by an increment, and which is operable in a second mode, upon operation of the actuating mechanism, to decrease the spacing between the discs by a second amount and so decrease the second speed by an increment.
- If a single actuator is used then the actuator, which typically is a solenoid, must be capable of exerting sufficient force, within a defined period, to operate effectively.
- The aforementioned discs may, generally, be of the type described in the earlier specification. A drive chain may be used to transfer rotational drive from the input drive to the output drive and the drive chain may, in general terms, be similar to what has been described in the earlier specification.
- The input drive may include an input shaft which is rotatable about the input axis, an idler which is mounted for rotation about the input axis, a first swing arm which is mounted for limited pivotal movement about the input axis, a first drive sprocket on the first swing arm, a second swing arm which is mounted for limited pivotal movement about the input axis, a second drive sprocket on the second swing arm, the drive chain being engaged with the first and second drive sprockets and passing over the idler, and a gear assembly which, upon rotation of the input shaft, causes rotation of the first and second drive sprockets thereby to cause rotation of the output drive.
- The swing arms may extend from the input axis in divergent directions, which vary as the drive ratio (the ratio of the second speed to the first speed) changes. The swing arms, for any given directions i.e. operative positions, may be mounted to have a small degree of pivotal movement. This may be achieved by providing a first stop which restricts pivotal movement of the first swing arm when a first portion of the drive chain between the first sprocket and the output drive is tensioned. Similarly a second stop may be provided which restricts pivotal movement of the second swing arm when a second portion of the drive chain between the second sprocket and the output drive is tensioned. The first stop may include a first biasing mechanism which acts to tension the first portion of the drive chain when the second portion of the drive chain is tensioned and, similarly, the second stop may include a second biasing mechanism which acts to tension the second portion of the drive chain when the first portion of the drive chain is tensioned.
- The first and second drive sprockets may be mounted to respective shafts for relative axial movement along the shafts when the spacing between the first and second discs is varied.
- The machine preferably includes a mechanism which, in response to incremental changes in the second speed, adjusts the tension in the drive chain by adjusting the positions of the swing arms. Power can flow through the machine in different directions. For example, in a vehicular application, power is transferred from an engine through the machine to drive wheels of the vehicle. If however engine braking takes place e.g. the vehicle goes downhill with reduced engine power output, power flows through the machine in a reverse direction. In order to reduce chain tension on the idler and, effectively, to isolate the idler from chain tension effects when power is output by the output drive a portion of the drive chain between the first drive sprocket and the output drive is tensioned, and when power is input to the output drive a portion of the drive chain between the second drive sprocket and the output drive is tensioned.
- The machine may include a support slide structure which is movable laterally relative to the output axis, and first and second guide idlers which are mounted to the support slide structure, which are engaged with the drive chain and which are spaced apart to form a gap through which opposing portions of the drive chain pass to, and from, the output drive respectively and wherein, in response to incremental movement of the cam arrangement, the support slide structure and the first and second guide idlers move and cause incremental pivotal movement of the first and second swing arms.
- Preferably the first stop is movable, in response to movement of the first swing arm and the action of the first biasing mechanism from a first stop position through a first gap with a maximum width of 2L, and the second stop is movable, in response to movement of the second swing arm and the action of the second biasing mechanism from a second stop position through a second gap with a maximum width of 2L and wherein the sum of the first gap and the sum of the second gap is 2L.
- A preload tension in the drive chain is preferably determined by the two biasing mechanisms.
- The invention is further described by way of example with reference to the accompanying drawings in which:
-
Figures 1A and1B are plan views of a variable transmission (IVT) machine according to the invention, and depict different drive transmission paths through the machine, -
Figure 2 is a perspective view of the machine, -
Figure 3 is a side view of part of the machine with certain components omitted in order to clarify the nature of underlying components, -
Figure 4 is an exploded view of part of an input drive unit of the machine, -
Figures 5 and 6 show output drive discs of the machine in an assembled, and exploded, configuration, respectively, -
Figure 6A is an enlarged view of a body on one of the output drive discs, -
Figure 6B shows further detail of the body ofFigure 6A , -
Figure 7 is similar toFigure 6 but shows the output drive discs from an opposing side to what is shown inFigure 6 , -
Figures 8 and 9 show an outer, and an inner, support slide, respectively, -
Figure 10 is a perspective view of a cam arrangement used in the machine, -
Figures 11 and 12 show an oscillating driver unit in perspective from opposing sides, respectively, -
Figures 13 and 14 are views of a locking plate included in the cam arrangement, -
Figure 15 is an exploded view of a solenoid actuator used in the machine, -
Figure 16 is a perspective view of a locking unit, -
Figures 17 and 18 are perspective views of first and second cams respectively, used in the cam arrangement, -
Figure 19 shows an actuating lever included in the cam arrangement, -
Figures 20 and 21 are perspective views from different angles from a drive input end of the machine, showing a chain positioning system, -
Figures 22 and 23 illustrate paths travelled by a drive chain in the machine while in a low ratio, and high ratio, mode respectively, and -
Figure 24 graphically shows parameters of the machine which vary during operation. - The accompanying drawings illustrate different aspects and parts of a
machine 10 according to the invention. The components of the machine are mounted in any appropriate housing 12 (shown notionally, when required, by a dotted line) in which are formed various slots and support structures, as may readily be determined by a person skilled in the art, to support components, moving or stationary, of the machine. - Referring for example to
Figures 1A ,1B ,2 and3 achain 14, located externally of the housing, passes overcogs input drive 26 and anoutput drive 28. -
Figure 4 shows, in an exploded configuration, the input drive 26 which includes aninput shaft 30 with aninput sprocket 32 at one end and abearing 33 at an opposed end. Ashaft 34 is positioned to one side of the input shaft and has asprocket 36 fixed to it which meshes with theinput sprocket 32. Theshaft 34 is formed withsplines 38. An axiallyslidable chain drive 40, which includes two spaced apartsprockets shaft 34. - A
drive shaft 34A is positioned on an opposing side of the input shaft. The shaft is similar in construction to theshaft 34 and carries achain drive 40A with similar components to thechain drive 40, which are identified with the suffix A. - The input drive includes a
lower swing arm 46, anupper swing arm 48 and atubular idler 50. - The
lower swing arm 46 has spacedarms tube 52. A projection on thearm 46A forms acam lever 54 with acam lobe 56. Thearms bearings - The
upper swing arm 48 is of similar construction to the lower swing arm and includes atube 62 from which extend spacedarms corresponding bearing - The
arm 48A is extended to form acam lever 66 with acam lobe 68. - The idler 50 is fitted with
inner needle bearings 70. - When the input drive is assembled the
shaft 30 extends through thetube 62 which is inside thetube 52. The idler 50 is on an outer side of thetube 52. - The
chain drive 40 is between thearms shaft 34 is supported by thebearings chain drive 40A is between thearms shaft 34A is supported by thebearings - The
sprockets Figure 1A ) which transfers drive between theinput drive 26 and theoutput drive 28, has the same pitch circle PC (seeFigure 22 ) as it passes over thesprockets idler 50. - Additional bearings, either not shown or not described, are provided as necessary between relatively rotatable parts of the input drive.
- The output drive 28 (see primarily
Figures 5, 6 and 7 ) has anouter disc 80 with aconical face 82 in which are formed a plurality of precisely positionedgrooves 84. The outer disc faces aninner disc 86 which has a generally similar construction i.e. a substantiallyconical face 88 in which are formed a plurality of precisely positionedgrooves 90. Anoutput drive shaft 92 is fixed to theouter disc 80. Atubular boss 94 extends from thedisc 80 and surrounds a part of theshaft 92. Two diametricallyopposed grooves 96 extend axially in an outer surface of the boss 94 - (only one groove is visible inFigure 6 ). Atubular formation 100 extends from thedisc 80 and surrounds and is spaced from an outer surface of theboss 94. - The
inner disc 86 has atube 102 which fits closely inside anannular gap 104 between opposing surfaces of theboss 94 and thetubular formation 100. An inner surface of thetube 102 is formed with diametricallyopposed grooves 108, seeFigure 7 . Ball-bearings, not shown, are located in thegrooves - The
cog 16 and the gear 24 (Figure 1A ) are fixed to an end of theshaft 92. - The
inner disc 86, on anouter face 114, has a raisedboss 118 which carries athrust bearing 120 and aneedle bearing 122. Theboss 118, on a surface which opposes theouter face 114, is formed with an axially orientedcam lobe 126 which has up and downramps 126A. 126B of equal magnitude. Each ramp extends through an angle of about 60°. The sum of the angles through which the ramps are operative is thus about 120°. This is reflected in the curve 590 inFigure 24 (described hereinafter) which graphically depicts the movement of a cam follower 316 (Figure 16 ) which rides on the cam lobe. - On its outer side 130 (
Figure 7 ) the outer disc has abearing 132 which supports theshaft 92. - A
ball screw arrangement 136 includes atube 138 with anexternal spiral groove 140. On an inner side thetube 138 hasneedle bearings 142 which are rotatably engaged with theshaft 92. Aworm gear wheel 144 at one end of the tube is backed by athrust bearing 146 and abearing 148 which is supported by thehousing 12. - A
ball screw unit 150 includes an inner hub 152 (Figure 7 ) which, on an inner surface, has a femaleball screw thread 154 which includes a feedback path for ball-bearings, not shown, which are mated with thespiral groove 140 on thetube 138. The inner hub extends from a generallycircular body 160 with arim 162 in which are formed a plurality of hemi-spherical indentations 164 at angular spacings of 45°. -
Figure 6A is an enlarged view of thebody 160 and illustrates in better detail constructional aspects of the body.Figure.6B shows, on a greater scale additional aspects of a portion of thebody 160. Thebody 160 has inwardly tapered lock holes 174 which are angularly spaced from one another by 45°. Each lock hole is centrally positioned between a respective adjacent pair ofindentations 164. A circular ball-bearingthrust groove 176 is located inwardly of the lock holes 174. - A circular raised
portion 180 on the body is formed with fourarcuate slots 182. Each slot extends through an angular displacement of 45° (as indicated) and follows a radius R relative to a centrallongitudinal axis 186 of theoutput drive shaft 92. Adjacent slots are angularly separated by 45° (as indicated). Each slot has tworamps central position 190 which is coplanar with an outer surface of the raisedportion 180, towards respectivedeep ends - A central
tubular formation 192, on thebody 160, supports awasher 194 which is held in position by means of a circlip, not shown. - An inner side of the
body 160 abuts thethrust bearing 120 and an outer surface of the inner hub 152 is engaged with an inner surface of thebearing 122. -
Figure 5 shows the assembledoutput drive 28. The effect of theball screw arrangement 136 is such that, if rotation of thetube 138 is constrained, rotation of thebody 160 in one direction will cause theinner disc 86 to be moved axially towards theouter disc 80. Conversely, counter-rotation of thebody 160 causes the axial displacement between thediscs -
Figure 8 shows anouter support slide 200 whileFigure 9 shows aninner support slide 202. Thesupport slide 200 has spacedplates rods 208A to 208D. Asmall plate 210 with acam surface 212 extends between the plates and is flanked by opposingslots plates 204. -
Extension pieces plate 206 carry stops 224 and 226 respectively at their extremities. The function and construction of the stops are described hereinafter. - The
inner support slide 202 has twoplates rods 232. Two closely spacedguide idlers suitable shafts - In the assembled machine the
inner support slide 202 is positioned between theplates rods 208A to 208D are passed through registering pairs ofholes 238A to 238D, respectively. The resultingcomposite slide assembly 239 is located between theinput drive 26 and the output drive 28 (seeFigure 2 ) and is supported by thehousing 12 of the machine so that it can move, as required, during operation of the machine with a sliding action away from the input drive and towards the output drive, and vice versa. - Referring to
Figure 2 , and to the schematic depictions inFigures 22 and 23 ., a chain 240 (shown notionally) passes through gaps between thechain drive 40 and the idler 50 on the one hand, and the idler 50 and thechain drive 40A on the other hand. Opposing portions of the chain pass through a gap between theguide idlers loop 241 between opposing surfaces of theouter disc 80 and theinner disc 86. The chain is engaged with thesprockets input drive 26 and theoutput drive 28. The chain has a plurality of pins which connect links of the chain to each other and ends of the pins, which project outwardly beyond the links, are engaged with thegrooves input drive 26 to theoutput drive 28 are generally in accordance with the description in the earlier specification and these aspects are not further elaborated on herein. - As stated earlier the pitch circle (PC) of the chain does not vary as it passes around the
sprockets idler 50. Thus tensile forces exerted by thechain lengths Figure 23 ) extending from the idler are minimal. The idler is thus effectively isolated from these forces. -
Figure 10 shows acomposite cam arrangement 242 which includes anoscillating drive unit 244, shown in different perspective views inFigures 11 and 12 , alocking plate 246 which is shown in different perspective views inFigures 13 and 14 , first andsecond cams Figures 17 and 18 respectively, and anactuating lever 252 shown inFigure 19 . - The locking
plate 246 has abody 262 with acentral bore 264 in which is located aneedle bearing 266. Twosolenoids respective plungers 272 positioned on centrallongitudinal axes longitudinal axis 280 of the bore. Eachaxis axis 280. This distance equals the radius R shown inFigure 6A . - The
body 262 has alobe 282 in which is formed ahole 284. - The
needle bearing 266, in the assembled form of the machine, is rotatably engaged with thetubular formation 192 on an outer face of thebody 160 shown inFigure 6 . -
Figure 15 shows the construction of the solenoid 270 - thesolenoid 268 is of identical construction. The solenoid has ahousing 290 in which is located an annularelectric coil 292. Aspring 294 which extends through the coil acts on theplunger 272 which is of tubular form and which is flanked by acircular rim 298 against which thecoil 292 bears. An outer end of the plunger is located in aplunger hole 300 in thebody 262. - The functioning of each solenoid is such that, with power applied to the
respective coil 292, the plunger is held in thecasing 290. If the power supply is interrupted the plunger is forced outwardly, away from the casing by virtue of the biasing force of thespring 294 and an outer extremity of the plunger then protrudes beyond asurface 304 of thebody 262. -
Figure 16 illustrates alocking unit 310 which includes aplate 312 from which extends ashaft 314. Acam follower 316 is attached to astud 318 which projects transversely from an end of theshaft 314. A lockingstud 320 is attached to theplate 312 by means of anut 322. The stud has atapered end 324. - The oscillating drive unit 244 (
Figures 11 and 12 ) includes aplate 342 with acircular hole 344. Alock structure 346, attached to the plate, has ablock 348 with upper andlower holes oscillating drive unit 244 also includes abearing plate 1000 with a thrustball bearing groove 1002, concentric with thehole 344, in which ball bearings (not shown) operate to mate and bear against the ball bearing thrustgroove 176 in thebody 160. - A
locator block 354 projects radially from theplate 342. Abolt 356 is threadedly engaged with a passage 358 (shown in dotted lines inFigure 12 ) which extends through the block. An inner end of the bolt bears against aspring 360 which in turn acts on aball bearing 362 which protrudes slightly through a mouth of the passage which, in the assembled configuration of the machine, is close to therim 162 of the body 160 (Figure 7 ) so that the spring loaded ball-bearing 362 can engage with a respective hemi-spherical indentation 164. This ensures that theball screw unit 150 is held in place, relative to thecam arrangement 242, according to operational factors at intervals which are angularly spaced by 45°. The engagement configuration is maintained until sufficient torque is applied to thebody 160 to enable the compressive force of thespring 360, which acts on theball bearing 362, to be overcome. Relative rotational movement between thelocator block 354 and thebody 160 can then take place, until the ball bearing enters the following hemi-spherical indentation. - A
stud 364 projects from theplate 342 and anangled lever 366, fixed to the plate, extends from the stud. A remote end of the lever has astud 368 which is slidably located in a first slot (not shown) in thehousing 12. Thestud 364 slides in a second slot (not shown) which is in the housing and which is parallel to the first slot. - Bearing pairs 370 and 370A, and 372 and 372A, respectively are provided on spaced
plates studs 382. Theplate 378 has aprojection 386 withparallel slots 388. Abase plate 394 straddles the slots and is connected thereto by means offasteners 396 which pass throughslots 398 in the base plate which are transverse to theslots 388. Aswivel stud 400 projects laterally from the base plate. Anotherstud 402 is centrally positioned on theplate 380 between thebearings - The first cam 248 (
Figure 17 ) includes acam profile 422 projecting from a splinedhollow shaft 424. Aspur gear 426 is carried by the shaft. The second cam 250 (Figure 18 ) has a splinedhollow shaft 432 which carries asecond cam profile 434 and aspur gear 436. - The actuating lever 252 (
Figure 19 ) is formed from two spacedplates cam follower 446 is rotatably mounted between the plates at an intermediate position. Apin 448 is mounted between the plates, on a front side of the cam follower, a distance C from a central axis of the cam follower.Slots 450 are formed in opposing surfaces of the plates on a second side of the cam follower. - The
cam follower 446 is located between the cam profiles 422 and 434 which act as a conjugate cam pair. -
Figure 10 illustrates how theoscillating drive unit 244, the lockingplate 246, the first and second cams, and the actuating lever, are assembled to make up thecomposite cam arrangement 242. Theswivel stud 400 passes through theslots 450. A central axis of the stud is a distance D from the rotational axis of the cam follower 446 (Figure 19 ). Thepin 448 is engaged with thehole 284 in thelocking plate 246. The first and second cams are respectively mounted to the opposed bearing pairs 370 and 370A, and 372 and 372A. Thebore 264 of thebody 262 is in register with thehole 344. Thelocking unit 310 is engaged with thelock structure 346. Theshaft 314 extends through theupper hole 348A while thestud 320 extends into thelower hole 348B. Thesprings plate 312. - The spur gears 436 and 426 of the two cams are meshed with an
intervening gear 480 which is mounted to thestud 402. The gear 22 (Figure 2 ), attached to asplined shaft 492 which extends through and drives thesplined shaft 424 of the first cam, has a diameter which is twice the diameter of thespur gear 24. - An
angled lever 500 has arectangular slot 502 which is slidably engaged with ablock 504 which is rotatably mounted to thestud 364. A pin (not shown), fixed to thehousing 12, is rotatably engaged with the lever by locating the pin in ahole 506. Alimb 508 of the lever extends through theslot 216 in theplate 206 of the outer support slide and bears on thecam surface 212 ― seeFigure 2 . A similar construction is provided at an opposinglimb 510 of thecam arrangement 242. - When rotational drive is imparted to the
input shaft 30 the chain drives 40 and 40A are rotated in opposite directions due to the meshingsprockets chain 240, engaged with the chain drives, is moved along a looped path of the type shown inFigures 22 and 23 and thediscs respective grooves output drive shaft 92. - If the
discs chain 240, when passing around the discs, travels on a substantiallycircular loop 241 of a relatively large radius R1, seeFigure 22 . Theswing arms composite slide assembly 239 is moved to the right towards the idler 50, to allow for the relatively large radius R1 of theloop 241. If the discs are moved apart the radius R2 of the chain looped around the discs is reduced, seeFigure 23 . The swing arms are pivoted away from the discs, to take up the resulting slack in the chain. The composite slide assembly moves to the left to maintain theloop 241 as close as possible to a circle. The angle of each swing arm to aline 520 which passes through the centres of rotation of the discs and of the idler 50 changes from aminimum angle 522, seeFigure 22 , to amaximum angle 524, seeFigure 23 . A significant benefit of this process is that the movement of the swing arms is such as to maintain thechain 240, essentially tensioned to the requisite degree, as operating conditions change. - The present invention is also concerned with providing a smooth and reliable change in the ratio of the output speed to the input speed of the machine, on an incremental basis, in an effective manner. Upon rotation of the output drive in one direction the
gear 22, meshed with thegear 24, drives the cam arrangement in a 2:1 ratio in the opposite direction. Thespur gear 426 is rotated together with thegear 22 and, via theidler gear 480, thespur gear 436 is rotated. Thecam follower 446 is acted on by the first and second cam profiles 422 and 434 and thelever 252 is thereby oscillated about thestud 400. Thepin 448 is connected to thelocking plate 246 which is oscillated through an amplitude of 45° about theaxis 280. The position of thelocking plate 246 is graphically depicted by acurve 566 inFigure 24 . The rotational velocity of the plate is shown by acurve 526. -
Figure 3 shows theactuating lever 252 in a central or reference position. Aline 530 shows the extent to which acentral axis 532, also referred to as a reference position, of the lever is deflected to a maximum angular extent in a clockwise direction about thestud 400 and aline 534 shows the central axis of the lever deflected to a maximum, equal, angular extent in an anticlockwise direction about the stud. - Due to the 2:1 ratio of the drive of the cam arrangement via the
gears discs lever 252 continues to oscillate as shown inFigure 3 and thelocking plate 246 oscillates in a counter direction to the lever. The taperedstud 320 of thelocking unit 310 is acted on, in one direction, by thecam follower 316 which rides on the upramp 126A of thecam lobe 126, carried by theinner disc 86. This action causes thetapered end 324 of thestud 320 to engage with the taperedlock hole 174, of thebody 160, which is in register with the stud. Thesprings cam follower 316 is on the up ramp, expand to cause the stud to disengage from thelock hole 174, when the cam follower is on thedown ramp 126B. During this period theball screw unit 150 is held in position by the spring-loaded ball bearing 362 (Figure 12 ) which is engaged with a respective hemi-spherical indentation 164 and theplungers 272 of the solenoids are retracted and held in the positions shown inFigure 13 . - The
tapered end 324 of thestud 320 repeatedly engages with, and disengages from, the respective tapered lock holes 174. In this way theball screw unit 150 is accurately aligned with theball screw arrangement 136 at periodic intervals - this is required particularly after ratio shifting has taken place. The position of thestud 324 is reflected by thecurve 580 inFigure 24 . - Ratio changing is preferably effected by means of an appropriate electronic control unit. The manner in which the control unit operates is apparent to one skilled in the art and is not described herein. What is required from the control unit is the ability to direct a signal to a selected solenoid at a precisely controlled interval which is related to the operation of the machine, in response to various input signals.
- When the drive ratio is to be altered, the electronic control unit determines in which direction the
ball screw unit 150 is to be rotated. Operation in one direction increases the ratio, while operation in the reverse direction decreases the ratio, in each case by a small increment. The electronic control unit then determines whichsolenoid curve 558 inFigure 24 shows movement of thecam follower 446, on each side of areference line 532A which represents thereference axis 532 as thelever 252 oscillates. The cam profiles 422 and 434 producerespective dwell periods oscillating locking plate 246 is stationary. At the start of the appropriate dwell period power to the selectedsolenoid plunger 272 of that solenoid is immediately moved under the action of its biasingspring 294 to stand proud of thesurface 304. The solenoid selection is based on the rotation direction of the oscillating locking plate after its current dwell duration. The emergingplunger 272 is directed into engagement with the correspondingarcuate slot 182 in thebody 160. At the end of the dwell period the oscillating locking plate starts moving in the reverse direction and, as the plunger is engaged with the deep hole end of the arcuate recess, thebody 160 is thereby rotated together with the locking plate through 45°. In the process theball screw unit 150 is also driven through 45° and, depending on the direction of rotation of theunit 150, theinner disc 86 is moved towards or away from theouter disc 80 by a small predetermined amount. This results in an incremental change of the output speed of rotation compared to the input speed of rotation. - At the end of the 45° movement the oscillating locking plate reaches its next dwell period. At this point the
ball screw unit 150 is locked in position by the taperedstud 320 of thelocking unit 310 which engages with thecorresponding lock hole 174, in thebody 160, which is in register with the stud. The solenoid which had been deactivated is then re-energised by the control unit. Upon reverse rotation of the oscillating locking plate the plunger of this solenoid rides up theramp surface housing 290, by the energisedsolenoid coil 292. Any tendency of thebody 160 to move, due for example to frictional effects, is prevented by the engagement of the spring-loadedball bearing 362 with arespective indentation 164 in the rim of the body. This retention action is however readily overcome by the positive drive action of the respective solenoid plunger when engaged with the deep hole end of the correspondingarcuate slot 182. - An incremental change in the drive ratio can thus be effected, up or down, for every two rotations of the
discs - In this example the actuating mechanism includes two actuators (solenoids) to increase the output speed incrementally, and to decrease the output speed incrementally. A single solenoid can however be used to replace the two solenoids provided the coil of the single solenoid is sufficiently powerful to retract the solenoid plunger against the bias of a spring (equivalent to the spring 294) and against all frictional forces, at a speed which meets operational requirements. To do this the four
arcuate slots 182 on the raisedcircular portion 180 of theunit 150 are replaced by respective blind holes which are concentric with, and substantially of the same diameter as, the deep ends 190 of the slots. The single solenoid is then operated directly in place of the two solenoids to cause rotation of theunit 150 in one direction, or the other, through a predetermined angle. -
Figure 3 illustrates X and Y axes which are centred on the axis of theswivel stud 400 but which are shown displaced from this axis. The dimensions C and D marked inFigure 19 are shown inFigure 3 . The central axis of thestud 400 can be adjusted in the X-direction, or in the Y-direction, within reason, according to requirement, by moving theplate 394 in one way or the other after thefasteners 396 have been loosened. The degree of movement, possible in this way, is limited by the dimensions of theslots cam follower 446 is Q, thenstud 400 is adjusted in the positive X direction by an amount x thenoscillating locking plate 246 oscillates through exactly 45° around theoutput shaft 92. The angular direction of the plate in each direction, from a neutral or reference line, is 22,5°. - A further factor is that by adjusting the
stud 400 in the Y direction a phase shift of oscillation of theoscillating locking plate 246 is achieved. This adjustment can be used to ensure that the solenoid units are precisely in register with the respective deep hole ends of the recessedslots 182 during the cam dwellperiods Figure 24 . - Ends of the
chain 240 must be positioned to engage accurately with the grooves in the discs. This alignment can be affected by wear, temperature and by torque applied to or generated in the machine. - Further adjustment, which can take account of these factors, to ensure synchronisation of the machine, is possible by means of a
worm gear 600 which is mounted to ashaft 602 which is rotatably supported by thehousing 12. Theworm gear 600 is engaged with the worm gear wheel 144 -Figure 3 . Theshaft 602 could be rotated by an electrical motor, not shown, in small increments, preferably under the control of the electronic control unit referred to, to ensure precise adjustment of the operation of the machine on an ongoing basis. Rotation of theshaft 602 causes rotation of theball screw arrangement 136, relative to theunit 150, and causes movement of thedisc 86 relative to thedisc 80. The adjustment of the worm gear could be done in response to an algorithm established after calibration routines. Alternatively it could be done by a processor which operates in a real time, feedback mode to ensure precise synchronisation. - When the
disc 86 is moved away from thedisc 80, thestud 364 is moved in the same direction. Thelever 366, restrained by the sliding movement of thestud 368 in a slot in thehousing 12, also moves in a straight line 604 - seeFigure 1A . Thelever 500 which is mounted to the housing for rotation about thehole 506, is rotated by the relative sliding/rotating movement of theblock 504 and thelimb 508, which extends through theslot 216, then acts positively on thecam surface 212 and thecomposite slide assembly 239, and hence theidlers chain 240 and keep the loop 241 (Figure 23 ) as close to circular as possible. When thedisc 86 is moved towards thedisc 80, thelimb 508 which, due to thesprings 606, at all times remains in contact with thesurface 212, is allowed to rotate in a controlled movement in a direction which is away from thecam surface 212. The composite slide assembly can then move towards the chain drives 40 and 40A. Theidlers swing arms Figure 22 . Again the chain tension is maintained. - The
stops Figure 20 in that each stop includessprings 606, inside ahousing 608, which bias asupport plate 610 outwardly. The cam lobes 56 and 68 of the swing arms, described in connection withFigure 4 , bear against therespective support plates 610.Figure 20 shows only thelower lobe 68. In a neutral position the spacing between each support plate and its housing is a distance L. The small degree of relative movement which is permitted and controlled by this arrangement is important for one of the swing arms (46 or 48) experiences a larger force than the other swing arm (48 or 46 as the case may be) when the machine is outputting power, or when the machine is absorbing power, for example due to engine braking. - Referring for example to
Figure 23 if the chain is moving in the direction of anarrow 650 and power is transmitted from the input drive to the output drive (e.g. for a vehicle going uphill) then anupper chain portion 652 is subjected to high tension while alower chain portion 654 undergoes a reduced tension as thechain drive 40 acts as the input driver. A converse situation would result if power is transmitted from the output drive to the input drive for thechain drive 40A would act as the input driver (e.g. for the vehicle going downhill). In each instance a substantial amount, if not all, of the resulting slack in the chain, not taken up by the adjusting action of the composite slide assembly, is absorbed by the spring-loaded stops. The high tension portion (say 652) exerts force on the corresponding cam lever which causes the gap L on the corresponding stop to be reduced to zero. On the other hand the gap on the other stop is doubled to 2L. This causes a preload tension in the chain section which otherwise would have a much reduced chain tension. The benefit of this feature is that the part of thechain 240, between the chain drives 40 and 40A, which passes over the idler 50, is only subjected to the preload tension in the chain, and not to the load tension in the chain. - The
chain 240 tends to push thediscs disc 80 is however not axially movable. The swing arms act as stops which, via the respective levers, exert a force on the ball screw arrangement (on the outer side of the disc 86) which tends to push thedisc 86 towards thedisc 80, to counteract the effect of the chain. - When the ratio of the machine is adjusted it is necessary for the chain drives 40 and 40A to be moved axially along the respective
splined drive shafts Figures 20 and 21 illustrate achain positioning system 700, which acts on thechain drive 40A, and which assists in achieving this function. Theupper chain drive 40 has a similar system. The system includes acompression spring 702 on thedrive shaft 34A which acts between thearm 46A and thesprocket 42A. Apin 704 which is slidably located in a passage formed in theshaft 34A at one end, has acircular disc 706 which bears against the ends of push-plates 708 which are slidably located incorresponding grooves 710 of spline formations in the shaft. The pin has a hemi-spherical end 712 which bears against asloped rib 714 of a chain position guide 716 mounted in asemicircular slot 718 in thehousing 12. - When ratio changing takes place the end of the pin rides over the
sloped rib 714 in one direction or the other according to the movement of theswing arms Figure 23 , the pin is urged to the left (referring toFigure 21 ) by the slopedrib 714 and thesprockets spring 702 is compressed. If thearms Figure 22 ) the pin can move to the right and thus exerts less pressure on the spring which then moves thesprockets - It is possible to increase the range of ratio adjustment by using a method similar to that described in the specification of application No.
WO 2007030840 (the "second specification"). This is based on the principle of transmitting power in different directions through a variable part of the transmission in a low range and in a high range, generally as described in the second specification. -
Figures 1A and1B depict aninput transmission shaft 800 on which is located a freelyrotatable hub 802 which includes thechain drive 14 to theoutput drive shaft 92, achain drive 806 to a freelyrotatable sprocket 808 on atransmission output 810, and agear drive 812 to a freelyrotatable gear 814 located on thetransmission output 810. A freelyrotatable gear 816 is located on thetransmission input shaft 800 and is meshed with agear 818 which is fixed to theinput shaft 30. - A
dog clutch 820 is used to couple theinput shaft 800 to thegear 816 or to couple theshaft 800 to thehub 802, according to requirement. - A
second dog clutch 822 is used, as required, to couple thetransmission output 810 to thegear 814, or to couple theoutput 810 to thegear 818 while having a central neutral position. - A
third dog clutch 824 couples thetransmission output 810 to thesprocket 808 or decouples these components, as the case may be. - In
Figure 1A and inFigure 1B asolid arrow line 900 indicates power input to the transmission and abroken arrow line 902 indicates power output from the transmission. - In low range operation (see
Figure 1 B) thedog clutch 820 couples thetransmission input shaft 800 to thegear 816 and thedog clutch 822 couples thetransmission output shaft 810 to thegear 814. Power thus flows from thetransmission input shaft 800 to thegear 816, then to thegear 818 and into the machine input end. Power then flows out of the machine to thechain drive 14 to thegear drive 812, to thegear 814 and then to thetransmission output shaft 810. Reverse is accomplished by decoupling thedog clutch 822 while using thedog clutch 824 to couple thesprocket 808 to thetransmission output shaft 810. - In high range operation (see
Figure 1A ) thedog clutch 820 couples thetransmission input shaft 800 to thehub 802. Thedog clutch 822 couples thetransmission output shaft 810 to thegear 818. Power thus flows from thetransmission input shaft 800 to thehub 802, through thechain drive 14 and into the machine. Power flows out of the machine to thegear 818 and to thetransmission output shaft 810. - During dog clutch shifting from the low range to the high range all components across the
respective dog clutches
Claims (16)
- A variable transmission machine (10) which includes an input drive (26) which is rotatable at a first speed about an input axis, an output drive (28) which is rotatable at a second speed, which is dependent on the first speed, about an output axis (186), a controller which is operable to vary the second speed, a cam arrangement (242) which, in response to rotation of the output drive, is oscillated between first (530) and second (534) positions through a reference position (532), and which is characterised in that it includes an actuating mechanism which is selectively operable when the cam arrangement (242) is at the first position to cause operation of the controller so as to increase the second speed by an increment, and which is selectively operable when the cam arrangement (242) is at the second position to cause operation of the controller so as to decrease the second speed by an increment.
- A machine according to claim 1 characterised in that the actuating mechanism includes a first actuator (268) and a second actuator (270), and wherein each actuator is selectively operable when the cam arrangement (242) is at the first position to cause operation of the controller so as to increase the second speed by an increment.
- A machine according to claim 2 characterised in that each actuator (268, 270) is selectively operable when the cam arrangement (242) is at the second position to cause operation of the controller so as to decrease the second speed by an increment.
- A machine according to claim 2 or 3 which is characterised in that it includes a body (160) which is mounted for rotation about the output axis (186) and which includes at least one formation which, upon selective operation of the actuating mechanism, is engaged with the actuating mechanism which is then constrained to rotate to a defined angular extent together with the body (160) about the output axis (186) in a first direction and which, upon counter-rotation of the body (160) in a second direction which is opposite to the first direction, is disengaged from the actuating mechanism.
- A machine according to claim 4 characterised in that the formation includes an arcuate slot (182), with a radius which is centred on the output axis (186), and with a ramped base which varies in depth.
- A machine according to claim 1 characterised in that the first position is a first limiting position (530) which is displaced by a first angle in a first direction of rotation from the reference position (532) and the second position is a second limiting position (534) which is displaced by the first angle in a second direction of rotation, which is opposite to the first direction, from the reference position (532) and wherein the actuating mechanism is operable during a first dwell period when the cam arrangement (242) is at the first limiting position (530), and actuating mechanism is operable during a second dwell period when the cam arrangement (242) is at the second limiting position (534) .
- A machine according to claim 2 characterised in that the first actuator includes a first solenoid (268) and the second actuator includes a second solenoid (270).
- A machine according to claim 1 characterised in that the output drive (28) includes axially aligned, opposing, first and second conical discs (80, 86) which are spaced apart and which are rotatable about the output axis (186), and the controller includes a screw assembly (136) which acts between the first and second discs and which is operable in a first mode, upon operation of the actuating mechanism, to increase the spacing between the discs by a first amount and so increase the second speed by an increment, and which is operable in a second mode, upon operation of the actuating mechanism, to decrease the spacing between the discs by a second amount and so decrease the second speed by an increment.
- A machine according to claim 1 which is characterised in that it includes a drive chain (240) which transfers rotational drive from the input drive (26) to the output drive (28), and wherein the input drive (26) includes an input shaft (30) which is rotatable about the input axis, an idler (50) which is rotatably mounted to the input shaft (30), a first swing arm (46) which is mounted for limited pivotal movement about the input axis, a first drive sprocket (40A) on the first swing arm (46), a second swing arm (48) which is mounted for limited pivotal movement about the input axis, a second drive sprocket (40) on the second swing arm (48), the drive chain (240) being engaged with the first and second drive sprockets (40A,40) and passing over the idler (50), and a gear assembly (32,36,36A) which, upon rotation of the input shaft (30) causes rotation of the first and second drive sprockets (40A,40), thereby to cause rotation of the output drive (28).
- A machine according to claim 9 which is characterised in that it includes a first stop (224) which restricts pivotal movement of the first swing arm (46) when a first portion (652) of the drive chain (240) between the first sprocket (40A) and the output drive (28) is tensioned, a second stop (226) which restricts pivotal movement of the second swing arm (48) when a second portion (654) of the drive chain (240) between the second sprocket (40) and the output drive (28) is tensioned, the first stop (224) including a first biasing mechanism (606) which acts to tension the first portion (652) of the drive chain (240) when the second portion (654) of the drive chain (240) is tensioned, and the second stop (226) including a second biasing mechanism (606) which acts to tension the second portion (654) of the drive chain (240) when the first portion (652) of the drive chain (240) is tensioned.
- A machine according to claim 9 characterised in that each drive sprocket (40,40A) is slidably mounted on a respective shaft (34, 34A) and which includes a respective biasing device (702) which biases the drive sprocket in a first direction along the shaft, and a cam mechanism (714) which acts on and which moves the chain sprocket, against the biasing device, to a degree which is varied as the swing arm which carries the drive sprocket is pivoted.
- A machine according to claim 9 which is characterised in that it includes an adjustment mechanism (200,202), responsive to an increment in the second speed, to adjust the tension in the drive chain (240) by adjusting the positions of the swing arms (46,48).
- A machine according to claim 9 characterised in that, when power is output by the output drive (28), a portion of the drive chain (240) between the first drive (40) sprocket and the output drive (28) is tensioned, and when power is input to the output drive (28), a portion of the drive chain (240) between the second drive (40A) sprocket and the output drive is tensioned, thereby to reduce tension in the drive chain (240) between the idler and each drive sprocket.
- A machine according to claim 10 which is characterised in that it includes a support slide structure (200) which is movable laterally relative to the output axis (186), and first (234) and second (236) guide idlers which are mounted to the support slide structure (200), which are engaged with the drive chain (240) and which are spaced apart to form a gap through which opposing portions of the drive chain pass to, and from, the output drive (28) respectively and wherein, in response to incremental movement of the cam arrangement (242), the support slide structure (200) and the first (234) and second (236) guide idlers move and cause incremental pivotal movement of the first and second swing arms (46,48).
- A machine according to claim 14 characterised in that the first stop (224) is movable, in response to movement of the first swing arm (46) and the action of the first biasing mechanism (606) from a first stop position through a first gap with a maximum width of 2L, and the second stop (226) is movable, in response to movement of the second swing arm (48) and the action of the second biasing mechanism (606) from a second stop position through a second gap with a maximum width of 2L and wherein the sum of the first gap and the sum of the second gap is 2L.
- A machine according to claim 15 characterised in that the drive chain (240) has a preload tension determined by the first and second biasing mechanisms (606).
Applications Claiming Priority (3)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
ZA200803783 | 2008-04-25 | ||
ZA200806882 | 2008-08-06 | ||
PCT/ZA2009/000031 WO2009132364A2 (en) | 2008-04-25 | 2009-04-23 | Incremental variable transmission |
Publications (2)
Publication Number | Publication Date |
---|---|
EP2268940A2 EP2268940A2 (en) | 2011-01-05 |
EP2268940B1 true EP2268940B1 (en) | 2011-10-26 |
Family
ID=41217458
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
EP09735836A Not-in-force EP2268940B1 (en) | 2008-04-25 | 2009-04-23 | Incremental variable transmission |
Country Status (10)
Country | Link |
---|---|
US (1) | US8540596B2 (en) |
EP (1) | EP2268940B1 (en) |
JP (1) | JP5537544B2 (en) |
KR (1) | KR101247485B1 (en) |
CN (1) | CN102076996B (en) |
AT (1) | ATE530805T1 (en) |
AU (1) | AU2009240410B2 (en) |
BR (1) | BRPI0911633A2 (en) |
WO (1) | WO2009132364A2 (en) |
ZA (1) | ZA201007407B (en) |
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
TWI474906B (en) * | 2011-11-22 | 2015-03-01 | Hon Hai Prec Ind Co Ltd | Gear transmission decice and robot arm having the same |
Families Citing this family (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US20140235385A1 (en) * | 2013-02-21 | 2014-08-21 | Armin Sebastian Tay | Cone with member cvt for which belt tension can be reduced |
CN103407745B (en) * | 2013-09-02 | 2015-12-23 | 四川方大新型建材科技开发有限责任公司 | Containing wet feed material lock wind feeder |
CN116725682B (en) * | 2022-09-06 | 2024-09-13 | 北京和华瑞博医疗科技有限公司 | Connecting device and surgical robot |
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CA1238102A (en) * | 1985-07-22 | 1988-06-14 | Joseph T. Woyton | Variable speed drive |
US4929218A (en) * | 1989-07-21 | 1990-05-29 | Clough Robert L | Continuously variable transmission |
NL1011732C2 (en) * | 1999-04-06 | 2000-10-09 | Skf Engineering & Res Services | Pulley kit for a continuously variable transmission unit. |
NL1019910C2 (en) * | 2001-10-22 | 2003-04-23 | Skf Ab | Continuously variable transmission with axially movable pulley hub units. |
WO2003056212A1 (en) * | 2002-01-04 | 2003-07-10 | Varibox (Pty) Limited | Angular velocity profile generator |
WO2004072511A1 (en) * | 2003-02-12 | 2004-08-26 | Varibox (Pty) Limited | Rotor controlled transmission |
US8393984B2 (en) * | 2003-10-13 | 2013-03-12 | Varibox (Pty) Limited | Infinitely variable transmission |
CN100564945C (en) * | 2003-10-13 | 2009-12-02 | 瓦里博克斯股份有限公司 | Stepless speed variator |
US7713153B2 (en) * | 2003-10-13 | 2010-05-11 | Varibox Ip (Pty) Limited | Infinitely variable transmission |
EP1673555B1 (en) | 2003-10-13 | 2007-04-18 | Varibox (Pty) Limited | Infinitely variable transmission |
US20050272540A1 (en) * | 2004-05-03 | 2005-12-08 | Starkey John M | Coaxial electrical actuator for continuously variable transmission |
US20060252589A1 (en) * | 2005-01-20 | 2006-11-09 | Tay Armin S | Adjuster systems for continuous variable transmissions |
EP1929183A1 (en) * | 2005-09-29 | 2008-06-11 | Infinigear AB | Gear assembly and constinuously variable transmission comprising such gear assembly |
CN101107465A (en) * | 2005-11-15 | 2008-01-16 | 瓦里博克斯股份有限公司 | Geneva motion machine controller |
WO2007059539A1 (en) | 2005-11-15 | 2007-05-24 | Varibox (Pty) Limited | Geneva motion machine controller |
JP4939040B2 (en) * | 2005-11-21 | 2012-05-23 | ヤンマー株式会社 | Belt type continuously variable transmission |
JP2007232147A (en) * | 2006-03-02 | 2007-09-13 | Yamaha Motor Co Ltd | Vehicle |
WO2010040153A1 (en) | 2008-10-02 | 2010-04-08 | Whitehead, Johannes, Lodewikus | Play ball assembled of eight identical liquid containers |
-
2009
- 2009-04-23 KR KR1020107026470A patent/KR101247485B1/en not_active IP Right Cessation
- 2009-04-23 CN CN200980124243.3A patent/CN102076996B/en not_active Expired - Fee Related
- 2009-04-23 EP EP09735836A patent/EP2268940B1/en not_active Not-in-force
- 2009-04-23 JP JP2011506508A patent/JP5537544B2/en not_active Expired - Fee Related
- 2009-04-23 AU AU2009240410A patent/AU2009240410B2/en not_active Ceased
- 2009-04-23 WO PCT/ZA2009/000031 patent/WO2009132364A2/en active Application Filing
- 2009-04-23 AT AT09735836T patent/ATE530805T1/en not_active IP Right Cessation
- 2009-04-23 US US12/989,459 patent/US8540596B2/en not_active Expired - Fee Related
- 2009-04-23 BR BRPI0911633A patent/BRPI0911633A2/en not_active IP Right Cessation
-
2010
- 2010-10-18 ZA ZA2010/07407A patent/ZA201007407B/en unknown
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
TWI474906B (en) * | 2011-11-22 | 2015-03-01 | Hon Hai Prec Ind Co Ltd | Gear transmission decice and robot arm having the same |
Also Published As
Publication number | Publication date |
---|---|
ATE530805T1 (en) | 2011-11-15 |
AU2009240410A1 (en) | 2009-10-29 |
CN102076996B (en) | 2014-10-15 |
JP2011518999A (en) | 2011-06-30 |
ZA201007407B (en) | 2011-07-27 |
BRPI0911633A2 (en) | 2019-09-24 |
WO2009132364A2 (en) | 2009-10-29 |
EP2268940A2 (en) | 2011-01-05 |
US20110039645A1 (en) | 2011-02-17 |
WO2009132364A3 (en) | 2010-03-18 |
KR101247485B1 (en) | 2013-04-02 |
CN102076996A (en) | 2011-05-25 |
KR20110021813A (en) | 2011-03-04 |
AU2009240410B2 (en) | 2013-08-29 |
JP5537544B2 (en) | 2014-07-02 |
US8540596B2 (en) | 2013-09-24 |
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